Author: Gershman, Sophia; Harreguy, Maria B.; Yatom, Shurik; Raitses, Yevgeny; Efthimion, Phillip; Haspel, Gal
Title: A low power flexible dielectric barrier discharge disinfects surfaces and improves the action of hydrogen peroxide Cord-id: af51b6ji Document date: 2021_2_25
ID: af51b6ji
Snippet: There is an urgent need for disinfection and sterilization devices accessible to the public that can be fulfilled by innovative strategies for using cold atmospheric pressure plasmas. Here, we demonstrate a successful novel combination of a flexible printed circuit design of a dielectric barrier discharge (flex-DBD) with an environmentally safe chemical reagent for surface decontamination from bacterial contaminants. Flex-DBD operates in ambient air, atmospheric pressure, and room temperature wi
Document: There is an urgent need for disinfection and sterilization devices accessible to the public that can be fulfilled by innovative strategies for using cold atmospheric pressure plasmas. Here, we demonstrate a successful novel combination of a flexible printed circuit design of a dielectric barrier discharge (flex-DBD) with an environmentally safe chemical reagent for surface decontamination from bacterial contaminants. Flex-DBD operates in ambient air, atmospheric pressure, and room temperature without any additional gas flow at a power density not exceeding 0.5 W/cm(2). The flex-DBD activation of a 3% hydrogen peroxide solution results in the reduction in the bacterial load of a surface contaminant of > 6log(10) in 90 s, about 3log(10) and 2log(10) better than hydrogen peroxide alone or the flex-DBD alone, respectively, for the same treatment time. We propose that the synergy between plasma and hydrogen peroxide is based on the combined action of plasma-generated OH(·) radicals in the hydrogen peroxide solution and the reactive nitrogen species supplied by the plasma effluent. A scavenger method verified a significant increase in OH(·) concentration due to plasma treatment. Novel in-situ FTIR absorption spectra show the presence of O(3), NO(2), N(2)O, and other nitrogen species. Ozone dissolving in the H(2)O(2) solution can effectively generate OH(·) through a peroxone process. The addition of the reactive nitrogen species increases the disinfection efficiency of the hydroxyl radicals and other oxygen species. Hence, plasma activation of a low concentration hydrogen peroxide solution, using a hand-held flexible DBD device results in a dramatic improvement in disinfection.
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